CN113358881B - Biomarker for NMOSD prediction or recurrence monitoring and application thereof - Google Patents
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Abstract
The invention discloses a biomarker for NMOSD prediction or recurrence monitoring and application thereof. By preparing a reagent or a kit capable of detecting and analyzing the expression level of the biomarker and detecting the corresponding biomarker in peripheral blood or plasma exosomes of a subject, prediction and monitoring of the neuromyelitis optica spectrum disease can be realized, the risk of the subject suffering from the neuromyelitis optica spectrum disease can be predicted, and relapse of the neuromyelitis optica spectrum disease of a patient or the subject can be monitored. The invention provides biomarkers for NMOSD prediction or recurrence monitoring, which are helpful for better understanding of NMOSD pathophysiology, thereby improving clinical service of NMOSD patients.
Description
Technical Field
The present invention relates to biomarker technology, and in particular to biomarkers useful for NMOSD analysis.
Background
Neuromyelitis optica (NMOSD) spectrum disease is an immune demyelinating disease of the central nervous system, mainly an acute or subacute demyelinating lesion in which the optic nerve, spinal cord are affected simultaneously or sequentially. It has long been controversial that NMOSD is an independent disease or a variant of Multiple Sclerosis (MS). Since Lennon et al (2004) found aquaporin 4 (AQP 4) antibodies in the serum of neuromyelitis optica (NMO) patients, NMOSD has been widely recognized as an independent disease distinct from MS, a humoral-major autoimmune central nervous system autoimmune disease. The generation mechanism is that specific antibodies generated by sensitized B lymphocytes bind complement, deposit and destroy AQP4 on the surface of astrocytes, and meanwhile, innate immune cells such as macrophages and eosinophils are chemotactic and exuded to secrete inflammatory factors, so that myelin sheath loss, axons and brain tissue necrosis are caused. The clinical manifestations are optic neuritis and acute transverse myelitis, which may have single or multiple attacks, with intervals of weeks, months or even years. Although there are treatment regimens recommended by small-scale clinical studies or expert consensus (including glucocorticoids, gamma globulin, azathioprine, and rituximab, etc.), there is no optimal treatment regimen for NMOSD to date due to the lack of a large sample randomized double-blind control clinical trial for NMOSD.
Due to heterogeneity of clinical presentation, severity of neurological disability after recurrence, and variability in treatment response, there is an urgent need for reliable, sensitive NMOSD biomarkers of onset, recurrence, and progression. Detection of AQP4 antibody (AQP 4-IgG) in serum can support the diagnosis of seropositive NMOSD. However, it is not clear whether AQP4-IgG levels correlate with disease activity, severity, response to treatment, or long-term outcome. In addition, biomarkers for seronegative NMOSD patients have not been identified and validated. Therefore, there is a broad prospect to establish and validate biomarkers that can be used to predict NMOSD prognosis and recurrence.
Univomic data analysis is usually used to explain the correlation between some characteristic biochemical indicators and some diseases, but cannot explain the complex causal relationship among them. Advances in technology have led to the "omics era," which has enabled us to collect and integrate data and information at different molecular levels. The integration of these multiple sets of mathematical data means that thousands of proteins (proteomics), genes (genomics), RNAs (transcriptomics), and metabolites (metabolomics) can be studied simultaneously. Artificial intelligence will provide new insights into complex biological systems and reveal networks of interactions between all molecular levels. The method combines experimental data of multiple molecular levels with a calculation model, and processes the system as a whole to facilitate data identification of diagnostic, prognostic or therapeutic value.
The biomarker can prompt the NMOSD pathophysiological process, has a prediction value on the occurrence risk of the NMOSD, and provides a basis for clinical diagnosis and treatment. However, no biomarker with high prediction value for the onset of NMOSD and the progression of diseases is known so far, and the clinical requirement cannot be met. Therefore, the search for the biological marker capable of rapidly and accurately predicting the occurrence, development and prognosis of the disease has important clinical application prospect. Meanwhile, the integration of data information and clinical information obtained through omics technology is helpful for better understanding of NMOSD pathological process and searching new intervention targets of NMOSD, thereby improving the clinical management of NMOSD patients.
Disclosure of Invention
In order to solve the problems in the prior art, the invention aims to provide a biomarker for NMOSD prediction or relapse monitoring and a specific application thereof.
In order to realize the purpose of the invention, the technical scheme of the invention is as follows:
in a first aspect, the present invention provides the use of any one or more of the following proteins as a neuromyelitis optica lineage disease biomarker in the preparation of a neuromyelitis optica lineage disease prediction or monitoring reagent or kit, the proteins comprising: APOE, SRGN, NACA, HABP2, BLVRB, PRG4, S100a8, S100a9, TRAP5, IGFBP5, ST13, FST, LTF, CFHR3, CALD1, PRDX1, PRDX4, PRDX5, GRB2, PLXNB2, TIMP1, tollp, DUSP3, MTPN, ARHGDIB, Wdr44, DBI, HSPB1, THBS1, MAPRE2, FLNA, RAB11A, SRI, IGLL1, TLN 1.
Further, the neuromyelitis optica lineage disease biomarker also includes any one or more of CD59, FGA, CXCL10, CXCL12, PDGFA, and CCL 5.
The meaning of "one or more" is: one, two, three, or more of the aforementioned proteins may be selected. Any number of any proteins selected to be arranged and combined in the protein range listed in the invention are all within the protection scope of the invention.
More preferably, the biomarker of the invention is derived from an exosome protein of peripheral plasma or astrocyte origin.
In a second aspect, the present invention provides an neuromyelitis optica lineage disease prediction or monitoring reagent comprising a reagent that detects the expression level of at least one of the following biomarkers in peripheral plasma or astrocyte-derived exosome proteins of a subject:
APOE,SRGN,NACA,HABP2,BLVRB,PRG4,S100A8,S100A9,TRAP5,IGFBP5,ST13,FST,LTF,CFHR3,CALD1,PRDX1,PRDX4,PRDX5,GRB2,PLXNB2,TIMP1,TOLLIP,DUSP3,MTPN,ARHGDIB,Wdr44,DBI,HSPB1,THBS1,MAPRE2,FLNA,RAB11A,SRI,IGLL1,TLN1。
further, the reagent also comprises a reagent for detecting the expression level of at least one of the following biomarkers in the peripheral plasma or astrocyte-derived exosome protein of the subject: CD59, FGA, CXCL10, CXCL12, PDGFA, CCL 5.
The agent is an agent that can detect the expression level or profile of the biomarker in peripheral plasma or astrocyte-derived exosome proteins of a subject.
In a third aspect, the invention provides a kit comprising the aforementioned prediction or monitoring agent.
In a fourth aspect, the present invention provides a neuromyelitis optica lineage disease prediction or monitoring system comprising:
(1) detecting a biomarker in a biological test sample from a subject comprising the prediction or monitoring agent of claim 4 or 5;
(2) comparing the detected expression level of the biomarker to a normal or reference expression level of the biomarker.
Further, according to the comparison result of the system, the risk of the optic neuromyelitis pedigree disease of the subject can be predicted or the occurrence of the disease can be monitored.
When the expression level of the biomarker is different from the normal or reference expression level, and the differential expression change is shown in table 1, the subject is indicated to have the risk of occurrence or recurrence of the neuromyelitis optica lineage disease.
Preferably, the biological test sample is a peripheral plasma or astrocyte-derived exosome protein.
The invention has the beneficial effects that:
the invention provides a biomarker for NMOSD prediction or relapse monitoring and application thereof. With these biomarkers, reagents or kits for neuromyelitis optica lineage disease prediction or recurrence monitoring can be prepared to predict a subject's risk of developing neuromyelitis optica lineage disease, or to monitor a patient or a subject for recurrence of neuromyelitis optica lineage disease.
The biomarker group provided by the invention is helpful for better understanding the pathophysiology of NMOSD, and provides new opportunities for diagnosis and prognosis, thereby improving the clinical service of NMOSD patients.
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The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.
FIG. 1 is the differential expression results of 41 biomarkers of the invention in peripheral plasma and astrocyte-derived exosome proteomic identification of NMOSD patients and healthy persons; among them, 19 up-regulated proteins and 22 down-regulated proteins were included.
FIG. 2 shows differentially expressed proteins screened by ELISA in example 4.
FIG. 3 is a graph showing the correlation between the concentration of SRGN, FGA, PRG4, CXCL12, S100A8 and CD59 proteins in example 4 and the progression of clinical disability in the acute phase of NMOSD.
FIG. 4 shows the specificity and sensitivity of detection of the combined biomarker groups SRGN/FGA, SRGN/HABP2, SRGN/PRG4, S100A8/CXCL12/CFHL3 in example 5.
Detailed Description
In the present invention, the words "comprising", "having", "including" or "containing" mean inclusive or open-ended and do not exclude additional, unrecited elements or method steps. Also, the terms "comprising," "having," "including," or "containing" are intended to be inclusive and mean that there may be additional, unrecited elements or method steps.
In the present invention, the term "about" means: a value includes the standard deviation of error for the device or method used to determine the value.
Although the disclosure supports the definition of the term "or" as merely an alternative as well as "and/or," the term "or" in the claims means "and/or" unless expressly indicated to be merely an alternative or a mutual exclusion between alternatives.
In the present invention, the term "neuromyelitis optica (NMOSD)" is an immunological demyelinating disease of the central nervous system, mainly manifested as an acute or subacute demyelinating lesion in which the optic nerve and the spinal cord are affected simultaneously or sequentially.
In the present invention, the term "Biomarker (Biomarker)" also referred to as "Biomarker" refers to a biochemical marker that can mark changes or changes that may occur in the structure or function of systems, organs, tissues, cells and subcellular cells. It can be used for disease diagnosis, disease staging judgment, or for evaluating the safety and effectiveness of new drugs or new therapies in target populations.
In the present invention, the term "diagnosis" and similar terms refer to the identification of a particular disease.
In the present invention, "risk assessment", "risk classification", "risk identification" or "risk stratification" of a subject (e.g., a patient) refers to the evaluation of factors including biomarkers to predict the risk of the occurrence of future events including the onset of a disease or the progression of a disease, so that treatment decisions about the subject can be made on a more informed basis.
In the present invention, the term "prediction" and related terms refer to a description of the likely outcome of a particular disorder (e.g., neuromyelitis optica spectrum disease).
Embodiments of the invention include "monitoring" a subject who may be at risk of developing neuromyelitis optica lineage disease. The subject may be a patient who has not been diagnosed with neuromyelitis optica lineage disease, but may be at risk for neuromyelitis optica lineage disease due to various clinical or medical assessments.
In the present invention, "sample", "biological sample", "test sample", "specimen", "sample from a subject" and "patient sample" are used interchangeably and can be a sample of blood, tissue, urine, serum, plasma, amniotic fluid, cerebrospinal fluid, placental cells or tissue, endothelial cells, leukocytes or monocytes. In some manner discussed herein or other manner known in the art, may be used to obtain a sample directly from a patient, or the sample may be pretreated (e.g., by filtration, distillation, extraction, concentration, centrifugation, inactivation of interfering components, addition of reagents, etc.) to alter the characteristics of the sample.
In the present invention, "label" and "detectable label" generally refer to a detectable moiety that is directly or indirectly linked to an analyte binding molecule (e.g., an antibody or analyte-reactive fragment thereof) or an analyte to allow a reaction between the analyte binding molecule (e.g., an antibody or analyte-reactive fragment thereof, a nucleic acid probe, etc.) and the analyte, and the analyte binding molecule (e.g., an antibody or analyte-reactive fragment thereof) or the analyte so labeled is referred to as "detectably labeled". The label may produce a detectable signal (e.g., by visual or instrumental means). In some aspects, the label may be any signal-generating moiety, and is sometimes referred to herein as a reporter. As used herein, a label (or signal-generating moiety) generates a measurable signal that can be detected by external means (e.g., by measuring electromagnetic radiation), and depending on the system employed, the level of signal can vary to the extent that the label is in the environment of a solid support (e.g., an electrode, particle, or bead).
In the present invention, the methods for detecting the level of the biomarker include Western blot analysis, protein/peptide functional assay, immunohistochemical analysis, ELISA analysis. Illustratively, the above methods can be used to detect proteins.
In the present invention, 19 upregulated proteins and 22 downregulated proteins, identified by proteomics of peripheral plasma and astrocyte-derived exosomes, that can be used to predict neuromyelitis optica lineage disease are all known in the art. In particular, the present invention relates to a method for producing,
"APOE" means "apolipoprotein E"; "SRGN" means "serum glycerol"; by "CD 59" is meant "CD 59 glycoprotein, a potent inhibitor of the action of the complement Membrane Attack Complex (MAC). "; "NACA" means "nascent polypeptide-related complex"; "HABP 2" means "hyaluronic acid binding protein 2"; "BLVRB" means "riboflavin reductase"; "PRG 4" means "proteoglycan 4"; "FGA" means "fibrinogen alpha chain"; "S100A 8/A9" means "calcium binding protein S100-A8/A9"; "TRAP 5" means "tartrate-resistant acid phosphatase 5"; "IGFBP 5" means "insulin-like growth factor binding protein 5"; "ST 13" means "heat shock protein 70 interacting protein"; "FST" means "follicle-inhibiting protein"; "LTF" means "lactoferrin"; "CFHR 3" means "complement factor H-related protein 3"; "CXCL 10" and "CXCL 12" mean "C-X-C motif chemokine 10 and C-X-C motif chemokine 12", respectively; "CALD 1" means "calmodulin binding protein"; "PRDX 1" means "" PRDX1, PRDX4 and PRDX5 "means" peroxidase-1, peroxidase-4 and peroxidase-5, which are thiol-specific peroxidases catalyzing the reduction of hydrogen peroxide and organic hydroperoxides to water and alcohol. ";
"GRB 2" means "growth factor receptor binding protein"; "PLXNB 2" means "plexin B2"; "TIMP 1" means "metalloproteinase inhibitor 1"; "TOLLIP" means "toll-interacting protein"; "DUSP 3" means "bispecific protein phosphatase 3"; "MTPN" means "dystrophin"; "ARHGDIB" means "Rho-GDP dissociation inhibitor 2"; "Wdr 44" means "wd repeat protein 44"; DBI means "acyl-coa binding protein"; "PDGFA" means "platelet-derived growth factor a subunit"; "HSPB 1" means "heat shock protein β -1"; THBS1 means "thrombospondin-1"; "CCL 5" means "c-c motif chemokine 5 subtype 1"; "MAPERE 2" means "microtubule-associated protein rp/eb family member 2"; "FLNA" means "seramin-A"; "RAB 11A" means "ras-related protein RAB-11 a"; "SRI" means "soluble drug resistance-associated calcium binding protein"; "IGLL 1" means "immunoglobulin lambda-like polypeptide 1"; "TLN 1" means "ankyrin-1".
In the present invention, the 19 upregulated proteins and the 22 downregulated proteins that can be used to diagnose neuromyelitis optica lineage disease are all proteins known in the art that can be detected by methods known in the art for detecting proteins, such as by preparing corresponding antibodies.
The Molecular biological methods used in the present invention can be found in publications such as "Current Protocols in Molecular Biology, Wiley published" and "Molecular Cloning Manual, Cold spring harbor Laboratory published" and the like.
All reagents used in the examples were commercially available unless otherwise noted.
In order that the above objects, features and advantages of the present invention may be more clearly understood, a solution of the present invention will be further described below. It should be noted that the embodiments of the present invention and features of the embodiments may be combined with each other without conflict.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those described herein; it is to be understood that the embodiments described in this specification are only some embodiments of the invention, and not all embodiments.
Preferred embodiments of the present invention will be described in detail with reference to the following examples. It is to be understood that the following examples are given for illustrative purposes only and are not intended to limit the scope of the present invention. Various modifications and alterations of this invention will become apparent to those skilled in the art without departing from the spirit and scope of this invention.
Example 1: clinical data collection for NMOSD patients and healthy controls
The study was included in the beijing tiantan hospital inpatients affiliated with the capital medical university from 10 months in 2018 to 11 months in 2019. NMOSD patient enrollment criteria: (1) the onset age is 18-80; (2) the NMOSD patient is definitely diagnosed according to the NMOSD diagnosis standard of Wingerchuk in 2015; (3) blood AQP4 antibody positive; (4) this time is an acute attack: (a) neurological symptoms such as optic neuritis, transverse myelitis or acute brain injury which are newly developed or significantly worsened earlier (i.e. the patient must visit within 7 days after the onset of symptoms). (b) New onset symptoms must last for at least 48 hours or more and cannot be attributed to other clinical factors (e.g. fever, infection, injury, adverse effects on concomitant medications). (c) The new symptoms must conform to objective clinical signs of sensory, motor, or visual acuity impairment as confirmed by the clinician. (d) A single episode of episodic symptoms (e.g., tonic spasm) is not considered an acute episode. (e) No apparent change in clinical findings, fatigue, mood changes, sensory symptoms of bladder/stool urgency or incontinence were sufficient to determine the presence of an acute episode. Inclusion of clinical information includes: general basic information and clinical characteristics of patients, Kurtzke's Expanded Diagnosis Status Scale (EDSS) score, blood and cerebrospinal fluid related indexes, and acute phase treatment scheme. The follow-up data comprises: EDSS scores at onset, 3 months, 6 months, 1 year after onset, number of relapses, blood routine and biochemical indices, and imaging data, and remission stage treatment regimens.
Example 2: sample collection and storage for NMOSD patients and healthy controls
1. Collection of plasma: collecting peripheral blood in a purple tube containing anticoagulant EDTA or heparin, centrifuging within 30min after collecting the sample, 10min at 3000rpm, and 2-8 deg.C. The upper plasma was collected and stored in portions at-80 ℃. The samples were protected from repeated freeze thawing. Note that: the sample should be sufficiently centrifuged to avoid hemolysis or the presence of particles.
2. Extraction of exosomes from peripheral plasma
An immunoadsorption method is adopted to extract exosomes derived from astrocytes in plasma.
2.1 magnetic bead (Beads) coated antibodies
1) Adding 100ug of astrocyte surface glutamate transporter antibody (EAAT 2-IgG) into an ultrafiltration tube, and repeatedly washing;
2) adding Biotin (Biotin) with a final concentration of 10mM to 8-10ul into IgG, and standing at room temperature for 1-2 hours;
3) adding IgG-Biotin into Beads, and shaking in a shaking table at 360 ℃ for 2 hours at room temperature;
4) turning over the magnetic Beads (IgG-Beads) combined with the antibody up and down for 20 times, placing the magnetic Beads on a magnetic frame, standing for 1min, sucking out supernatant, adding 1ml of PBS, repeating the steps for 3 times, and adding 1ml of 0.1% PBSA;
5) an appropriate amount of 10mM Biotin was added at a ratio of 2mg of Beads to 6ul of 10mM Biotin, and vortexed at Vortex for 2 hours at room temperature.
2.2 extraction of exosomes
1) Taking out the sample, and adding a proper amount of Protease Inhibitor (PIC);
2) centrifuging at 2000G and 4 deg.C for 15min to obtain supernatant; 14000G, centrifuging for 30min at 4 ℃ and taking the supernatant;
3) adding 500ul of sample into 100ul of IgG-Beads, and rotating for 20 hours at 360 degrees at 4 ℃;
2.3 elution of exosomes
1) Adding 70ul of 0.1mol/L glycine (pH = 3.0) to the sample after binding IgG-Beads, and shaking at room temperature for 15 minutes;
2) placing into a magnetic frame, standing for 1min, collecting supernatant, adding 5ul 1mmol/L Tris (pH = 7.0) into the supernatant, and repeating the above steps for 1 time;
2.4 exosome quantification
1) NTA particle tracer (Nanosight)
2) Appearance observed by TEM (transmission electron microscope)
3) Western blot detection of exosome specific protein
3. Extraction of exosome proteins
1) Adding a suitable amount of SDSL 3-free, EDTA-containing 1XCocktail at final concentration to the exosome sample, placing on ice for 5 minutes, and adding DTT at final concentration of 10 mM;
2) performing ultrasonic treatment in ice bath for 2 minutes, centrifuging at 25,000g and 4 ℃ for 15 minutes, and taking supernatant;
3) adding 10mM DTT to the solution, and carrying out water bath at 56 ℃ for 1 hour;
4) adding final concentration 55mM IAM, and standing in dark room for 45 min;
5) 25000g, centrifuging at 4 ℃ for 15min, and taking the supernatant, wherein the supernatant is the protein solution.
Example 3: the proteomics technology analysis is carried out to screen out the differential expression protein and obtain the detection combination of the prognosis evaluation biomarker
1. The invention adopts the next generation non-labeled quantitative proteomics technology to complete analysis, can provide unparalleled proteome coverage in a Data Independent Acquisition (DIA) mode, and simultaneously realizes accurate and highly repeatable quantification of a large amount of proteins in each sample. The DIA protocol provides an ideal qualitative analysis of differentially expressed proteomes or a quantitative platform for proteomes of large numbers of samples. The DIA flow is based on three essential steps:
1) constructing a spectrogram library: the spectrogram library collects all detectable non-redundant high-quality peptide fragment information (MS/MS spectrogram) of a sample, and the MS/MS spectrogram serves as a peptide fragment identification template for subsequent data analysis. Including fragment ion intensities and retention times that characterize the peaks of the peptide fragment spectra. The spectrogram library is constructed using data collected from Data Dependent Acquisition (DDA) assays performed on a sample of interest.
2) A large amount of sample data is acquired in DIA mode: the Data independent acquisition (DIA, also called SWATH) mode simultaneously acquires the ion characteristics of the peptide fragment in terms of mass number and retention time by using the latest high-resolution mass spectrum. Compared with the traditional method for extracting single ion for fragmentation analysis, the mass spectrum in DIA mode is set as an analysis mode for circularly collecting a wide parent ion window and simultaneously fragmenting multiple peptide fragment ions. The method realizes complete collection of all detectable protein peak information in the sample, thereby being capable of analyzing a large number of samples with high repeatability.
3) Data analysis, how to better perform protein detection and quantification in the DIA-based discovery-type proteomic studies, is still a great challenge today. The information collected for the peptide fragments, while quite complete, was found to be highly convoluted. At this step, the data was accurately characterized and quantitatively analyzed using Spectronaut for efficient deconvolution.
2. The results of the screened differentially expressed proteins are as follows (table 2):
in NMOSD, peripheral plasma and astrocyte-derived exosome proteomics identified 19 upregulated proteins and 22 downregulated proteins with fold change > 2, P < 0.05; all dysregulated proteins are primarily involved in signaling and immune system regulation, including immune and inflammatory responses, cell proliferation and repair, cell adhesion junctions, etc. (figure 1).
Example 4: ELISA quantitative verification is carried out on the screened differential expression protein
In this example, the target protein is verified by enzyme-linked immunosorbent assay (ELISA) with high specificity and high sensitivity. From the results of the validation, the concentrations of APOE, SRGN, CD59, HABP2, PRG4, FGA, S100a8, LTF, CXCL10 and CXCL12 proteins in the plasma of NMOSD patients were significantly higher than those in the plasma of healthy controls (fig. 2), similar to the results obtained in example 3. The increase of the concentration of SRGN, FGA, PRG4, CXCL12 and S100A8 protein promotes the development of the clinical disability degree in the NMOSD acute stage, while the CD59 protein plays a protective role in the NMOSD acute stage (figure 3).
Example 5
In this example, when the target proteins are screened, the combined detection effect (specificity, sensitivity, etc.) of the combined biomarker groups SRGN/FGA, SRGN/HABP2, SRGN/PRG4, S100A8/CXCL12/CFHL3 is superior to that of each single biomarker, and has statistical significance. The S100A8/CXCL12/CFHL3 group is the combined biomarker group with the highest detection efficiency (figure 4). The expression "the highest detection efficiency" is: higher sensitivity and accuracy are achieved with less biomarker, lower detection cost and simpler detection operation.
The foregoing are merely exemplary embodiments of the present invention, which enable those skilled in the art to understand or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims (3)
1. The use of any one of the following proteins as a neuromyelitis optica lineage disease biomarker in the preparation of a reagent or a kit for predicting or monitoring neuromyelitis optica lineage disease, wherein the protein comprises: SRGN, HABP2, PRG4, FGA, S100a8, LTF, CFHR 3; the biomarkers are from peripheral plasma or astrocyte derived exosome proteins.
2. Use of any of the following proteins as neuromyelitis optica lineage disease biomarkers in the preparation of a reagent or kit for neuromyelitis optica lineage disease prediction or monitoring, wherein the proteins comprise: SRGN, HABP2, PRG4, FGA, S100a8, LTF, CFHR3, APOE, CD59, CXCL10, CXCL 12; the biomarkers are from peripheral plasma or astrocyte derived exosome proteins.
3. The use according to claim 2, wherein the protein is the combined biomarker group SRGN/FGA, SRGN/HABP2, SRGN/PRG4 or S100a8/CXCL12/CFHL 3.
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US7101679B2 (en) * | 2003-11-25 | 2006-09-05 | Mayo Foundation For Medical Education And Research | Marker for neuromyelitis optica |
US20100204058A1 (en) * | 2009-01-28 | 2010-08-12 | Howard Yuan-Hao Chang | Profiling for Determination of Response to Treatment for Inflammatory Disease |
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CN113358881B (en) * | 2021-08-10 | 2021-11-30 | 首都医科大学附属北京天坛医院 | Biomarker for NMOSD prediction or recurrence monitoring and application thereof |
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